Myocyte ploidy in heart chambers of birds with different locomotor activity

The ploidy levels of atrio- and ventriculocytes were determined by means of cytofluorimetry in 31 species of birds. The obtained data were collated with postnatal growth rate, heart mass index, and relative masses of heart chambers. The difference between mean ploidy of cardiomyocytes in the left and right atrium is small (7.9+/-0.6%) and comparable to the difference in the masses of these chambers (10.5+/-0.8%). The difference between mean ploidy of atrio- and ventriculocytes is most pronounced for the left and right parts of heart (23.9+/-1.4% and 24.0+/-1.3%, respectively) and corresponds to considerable differences in the average masses of atria and ventricles (4.5-fold and 2.1-fold, respectively). The mean cardiomyocyte ploidy levels in the left and right ventricles differ only slightly, as in the case of atria (by 8.1+/-0.5%), whereas the average mass of the left ventricle is greater by 237+/-16%. This discord can be explained by peculiarities of the growth, which is nonproportionally faster in the left ventricle during the last stage of proliferative heart growth as compared to other chambers. The cardiomyocyte ploidy is higher in birds with a relatively small heart and lower ability to flight. Birds with a high locomotor activity in the adult state have an athletic heart (mass index >1%); they are fast growing, altricial species with a low heart workload in the early postnatal ontogenesis. Birds with a low locomotor activity at the adult state are precocial; they grow slowly and have a high locomotor activity from the first minutes of life. Thus, notwithstanding the fact that a greater elevation of cardiomyocyte ploidy level is acquired under a higher functional load (ventricles vs. atria, left vs. right part of the heart), it is associated with a lower functional potential of the organ at the adult state. The level of somatic polyploidy can be considered an indicator of developmental tensions arising due to a high workload during the growth of a given organ and deficiency of resources invested into this growth. J. Exp. Zool. 293:427-441, 2002.     

An assessment of the relative contribution of the processes of cellular proliferation, polyploidization and hypertrophy to the increase in liver mass at various stages in the postnatal development of rats

Changes in isolated hepatocyte dry mass, its ploidy and liver mass at different stages of the rat postnatal ontogeny were investigated. The determination of these processes and special calculation made it possible to estimate quantitatively a relative contribution of cell proliferation, polyploidization and hypertrophy, not associated with DNA synthesis to the increase in the liver mass at different stages of the rat development. During the first week after the rat's birth, its liver growth is provided by 61 and 39% with hepatocyte proliferation and hypertrophy, respectively. Between the 14th and the 21st days of development, when considerable functional changes occur in the rat liver, the contributions of proliferative and polyploidization processes, and of cell hypertrophy into the liver mass increasing are roughly identical. Later on, the contribution of cell hypertrophy into the liver growth is noticeably reducing to reach within 1-2 months only 1%. On this developmental stage the liver mass increment by 2/3 is provided due to cell proliferation and by 1/3--to its polyploidization. As a whole, the accelerated growth of the rat liver from the birth to sex puberty is described as follows: the contribution of processes of proliferation and polyploidization, and of cell hypertrophy correspond to 28, 30 and 42%, respectively; afterwards, the liver growth being retarded. Within the period from 2 to 6 months, the liver mass increase is provided mainly (up to 76%) by cell proliferation, the shares of polyploidization and cell hypertrophy being 8 and 16%, respectively.     

Progressive polyploidy in mouse liver following repeated hepatectomy]

Mouse liver regeneration after partial hepatectomy results in sharp changes of ploidy classes towards the increase of high ploidy cells and the decrease low ploidy ones. These changes retain during three months. Each following partial hepatectomy (till 3 times) intensifies the hepatocyte polyploidy with appearance of cells with 32--64 ploidy nuclei. The cell polyploidization stimulated by repeated regenerations is similar to that observed in normal postnatal liver growth.     

Patterns of DNA and chromosome variation during in vitro growth in various genotypes of potato

Patterns of variation in nuclear DNA content and chromosome number were analysed in a temporal sequence, during in vitro growth of calli and cell suspensions in two monohaploids, a dihaploid and a tetraploid of potato (Solanum tuberosum). The results showed that both polyploidization and aneuploidy occurred during the initial stages of callus induction in all the genotypes. With further growth of callus, the frequency and extent of polyploidy and aneuploidy increased. In addition, the patterns of DNA and chromosome variation in cell suspension cultures revealed continued mitotic activity and transmission of cells with higher ploidy levels and aneuploidy. The results suggest that endoreduplication as well as endomitosis are important mechanisms of polyploidization, and that chromosome lagging and non-disjunction contribute to the production of aneuploidy.The various genotypes cultured under the same in vitro growth conditions differed in genetic instability, as assessed from the rate and degree of polyploidization and aneuploidy. Monohaploids showed more rapid rate of polyploidization than the dihaploid and tetraploid potatoes. It was concluded that the differences in genetic stability were due to different ploidy levels and genetic make-up of the genotypes.     

Impact of neonatal cryptosporidial gastroenteritis on epigenetic programming of rat hepatocytes

Inflammation, malnutrition and growth retardation during critical time-windows of development play a powerful role in ontogenetic programming of the life-long risk to many adult diseases (including metabolic syndrome, obesity and diabetes). Cellular mechanisms and the accurate timing and duration of critical periods for the liver remain obscure. To resolve this problem, we developed a postnatal suckling-weanling rat model of mild, moderate, and acute gastroenteritis challenged by a protozoan parasitic spread throughout the whole world, namely Cryptosporidium parvum. The physiological state of the liver was evaluated by hepatocyte ploidy and protein content that were measured by cytophotometry and image analysis on isolated cells. Hepatocyte ploidy is known to irreversibly increase after stress and is associated with the decrease in liver physiological capacity. Hepatocyte hypertrophy reflects cell functional loading. From our results, cryptosporidiosis is able to provoke a burst in premature hepatocyte polyploidization and hypertrophy (in proportion to parasitic load), and thus plays an important role in epigenetic programming of hepatocyte structure and function. We revealed two sensitive periods in liver growth. The first period (the less sensitive) covers the time before the establishment of homoiothermy, i.e. 6-9 days after birth. The second period (the more sensitive) covers the time of weaning when the change of type of nutrition and the peak of hepatocyte polyploidization and differentiation occurs. Thus, our data provide direct evidence that phenomenon of ontogenetic programming is reflected at the cellular level.     

Relationship of hepatocyte ploidy levels with body size and growth rate in mammals.

To elucidate possible causes of the elevation of genome number in somatic cells, hepatocyte ploidy levels were measured cytofluorimetrically and related to the organismal parameters (body size, postnatal growth rate, and postnatal development type) in 53 mammalian species. Metabolic scope (ratio of maximal metabolic rate to basal metabolic rate) was also included in 23 species. Body masses ranged 10(5) times, and growth rate more than 30 times. Postnatal growth rate was found to have the strongest effect on the hepatocyte ploidy. At a fixed body mass the growth rate closely correlates (partial correlation analysis) with the cell ploidy level (r = 0.85, P < 10(-6)), whereas at a fixed growth rate body mass correlates poorly with ploidy level (r = -0.38, P < 0.01). The mature young (precocial mammals) of the species have, on average, a higher cell ploidy level than the immature-born (altricial) animals. However, the relationship between precocity of young and cell ploidy levels disappears when the influences of growth rate and body mass are removed. Interspecies variability of the hepatocyte ploidy levels may be explained by different levels of competition between the processes of proliferation and differentiation in cells. In turn, the animal differences in the levels of this competition are due to differences in growth rate. A high negative correlation between the hepatocyte ploidy level and the metabolic scope indicates a low safety margin of organs with a high number of polyploid cells. This fact allows us to challenge a common opinion that increasing ploidy enhances the functional capability of cells or is necessary for cell differentiation. Somatic polyploidy can be considered a "cheap" solution of growth problems that appear when an organ is working at the limit of its capabilities.     

Paradoxical relationship between protein content and nucleolar activity in mammalian cardiomyocytes.

It was recently demonstrated that polyploidization of the avian myocardium is associated with a reduction of cardiac aerobic capacity evaluated by the heart mass to body mass ratio (heart index). To investigate possible cellular correlates of polyploidization, the protein content and nucleolar activity per cell and per genome were examined by image cytometry in 21 mammalian species, differing in the degree of heart polyploidization and heart index. We found that average cardiomyocyte ploidy level correlates negatively with the animal heart index (r = -0.75, p < 10(-4)), i.e., the large heart of athletic mammals is polyploidized to a lesser degree than the relatively smaller heart of sedentary species, which confirms the picture observed in birds. The protein content per genome decreased with the elevation of cardiomyocyte ploidy level. This inverse correlation was especially pronounced with the removed effect of body mass (r = -0.79, p < 10(-4)). Surprisingly, these changes were accompanied by the increase of nucleolar activity per genome (r = 0.61, p < 10(-3)). In the two species, for which the microarray gene expression data were available (human and mouse), this increase was paralleled by the elevated expression of ribosomal protein genes (but there was no increase in the expression of tissue-specific genes). Thus, in the polyploid cardiomyocytes there is a misbalance between protein content per genome and ribosome biogenesis. The reduction of protein content (per genome) of polyploid cardio my ocytes should further curtail heart functionality (in addition to reduction of heart index), because it is known that cardio myocyte protein content consists of more than 90% contractile proteins. This finding makes doubtful a widespread notion that polyploidization is necessary for cell function. Because somatic polyploidization is associated with stressful conditions and impaired energetics, we suppose that additional genomes can serve for cell regeneration and as a defense against oxidative damage in the organs that work at the limit of their metabolic capacity.     

Neuronal Organization of Mammalian Stellate Ganglion in Postnatal Ontogenesis

The paper considers the problem of peculiarities of maturation of the stellate ganglion nerve elements in mammals of different species. This process differs in precocious and altricial animals. It has been shown that in spite of some individual peculiarities, the neurons, fibers, and conducting pathways in altricial animals are not, on the whole, completely formed morphologically and functionally. In the course of postnatal ontogenesis, not only an increase of cell sizes and development of dendrite tree, but also reorganization of nerve connections with target organ occur. The postnatal ontogenesis is also accompanied by an increase of the excitation transmission rate along the fibers and by their myelination. The asymmetry of the right and left stellate ganglia (SG) by their sizes and functional peculiarities, which exists in adult animals appears as soon as at early stages of postnatal development. The neural elements of precocious animals are changed to a lesser extent in postnatal ontogenesis and are, in many aspects, similar to those of adult organisms as early as at birth.     

Cardiomyocyte ploidy levels in birds with different growth rates

Cytofluorimetric study of ploidy levels in ventricular cardiomyocytes was carried out on 36 adult bird species belonging to 10 orders as well as on the quail Coturnix coturnix, of different ages. It was shown that polyploidization of quail cardiomyocytes occurs during the first 40 days after hatching and ends by the time growth is completed. In adult birds, the cardiomyocyte ploidy hardly changed at all. Interspecies comparison revealed that in the adult bird myocardium 2cx2 myocytes are predominant, accounting for at least 50% of the cell population. Multinuclear cells with three to eight diploid nuclei were widespread. The percentage of such cells was five to six times higher in precocial species than in altricial birds of the same weight. Myocytes with polyploid nuclei were rare. A significant interspecies variability of cardiomyocyte ploidy levels was observed. The most prominent differences were found between the precocial and the altricial birds. The mean number of genomes in cells correlated both with the body mass and with the growth rate of the birds. The differences between the precocial and altricial birds disappeared when a statistical method was used to eliminate the effect of the growth rate, but did not when the effect of body mass was eliminated. Among the altricial birds, which are generally immobile during growth, the cardiomyocyte ploidy levels also correlated more closely with growth rate than with body mass. The opposite was observed in the precocial birds, which are highly mobile from the first minutes of life. We conclude that the interspecies variability of bird cardiomyocyte ploidy levels is a result of changes in the balance between the cardiac functional load and the growth rate; this is manifested at the cellular level as a competition between the proliferation and differentiation of cardiomyocytes. J. Exp. Zool. 289:48-58, 2001.     

Human hepatocyte polyploidization kinetics in the course of life cycle

The processes of polyploidization in normal human liver parenchyma from 155 individuals aged between 1 day and 92 years were investigated by Feulgen-DNA cytophotometry. It was shown that polyploid hepatocytes appear in individuals from 1 to 5 years old. Up to the age of 50 years the accumulation rate of binucleate and polyploid cells is very slow, but subsequently hepatocyte polyploidization is intensified, and in patients aged 86–92 years the relative number of cells with polyploid nuclei is about 27%. Only a few hepatocytes in the normal human liver reach 16C and 8C×2 ploidy levels for mononucleate and binucleate cells respectively. Using a mathematical modeling method, it was shown that during postnatal liver growth the polyploidization process in human liver is similar to that in the rat, and that polyploid cells are formed mainly from binucleate cells. As in rats, prior to an increase in ploidy level, diploid human hepatocytes can pass several times through the usual mitotic cycles maintaining their initial ploidy level. After birth, only one in ten hepatocytes starting DNA synthesis enters the polyploidization process. At maturity about 60% of 2C-hepatocytes starting DNA synthesis divide by conventional mitosis, the rest dividing by acytokinetic mitosis leading to the formation of binucleate cells. During ageing the probability of hepatocyte polyploidization increases and in this period there are two polyploid or binucleate cells for every diploid dividing by conventional mitosis.     

Delay of rat hepatocyte polyploidization in liver growth inhibition during hypokinesia]

Young rats, weighing 55-59g, after being for 10 days in conditions of limited mobility, show a retardation of body growth as well as that of liver growth. The decrease in the rate of organ growth is accompanied by a reduction of the cell proliferation and by a delay in polyploidization of hepatocytes in the liver of experimental rats.     

Analysis of the postnatal growth of the mouse liver by estimating the hepatocyte count, their weight and ploidy

Changes in the total number of hepatocytes, their distribution by the ploidy classes, as well as changes in the protein content of the cells were studied in 0.5-6 month old mice. The data obtained made it possible to estimate quantitatively the contribution of different growth components: increase in cell number, hypertrophy and polyploidization of cells, to the total increase of the liver mass. From 2 weeks to 1 month, the liver mass is increased via polyploidization (by 70%) and hypertrophy (by 30%). From 1 to 2 months, the liver mass increases due to hyperplasia (by 65%) and polyploidization (35%). After 2 months, the liver growth is practically terminated. The calculated equivalent mass of the liver, i. e. derivative of all three growth components, coincides fairly well with the factual changes in the liver mass.     

Strain and site dependence of polyploidization of cultured rat smooth muscle

Smooth muscle cell (SMC) growth may play an important role in the pathogenesis of vascular diseases such as atherosclerosis and hypertension. Recent studies have demonstrated that, under different growth stimuli in vivo, SMC may respond by proliferation of diploid cells, polyploidization to the tetraploid (or even octaploid) state, or both. In this study, we used flow cytometry to evaluate the intrinsic tendencies of aortic SMC and nonarterial cells from rats of different strains, ages, and blood pressures to polyploidize in response to in vitro growth stimulation. Significant strain-related differences in polyploidization of aortic SMC were found (P less than 0.001): highest in WKY (normotensive inbred rat related to SHR), intermediate in SHR (genetically hypertensive rat), and lowest in Sprague-Dawley and Fischer (normotensive outbred and inbred rats). Animal age had less or no effect on the degree of polyploidization. Nonarterial cells (venous SMC and lung cells) from WKY and SHR remained essentially diploid, suggesting tissue specificity of in vitro polyploidization. Studies of the growth kinetics of uncloned and clonal populations of aortic SMC revealed decreased proliferation as the ploidy increased in WKY, SHR, and Sprague-Dawley. These findings suggest that genetic strain factors as well as cell type/site of origin significantly influence in vitro polyploidization, whereas animal age and blood pressure do not. The findings also emphasize the need to consider ploidy changes when evaluating in vitro SMC growth kinetics. Further studies will improve understanding of SMC growth regulation and the functional significance of vascular polyploidy.     

Fetal heart rate in relation to body mass

In contrast to the inverse relation of heart rate to body mass in adult mammals, the heart rate of immature fetuses is unrelated to body mass and approximately constant among different species. With maturation, fetal heart rate decreases in a large mammal but tends to increase in a small mammal. These maturational changes reduce the difference between the heart rate of a term fetus and the heart rate which is "appropriate for body mass" as calculated by means of the allometric equation for adults. The comparative physiology of fetal heart rate supports the hypothesis that immature fetuses of small and large mammals have similar oxygen consumption rates per unit body mass.     

Somatic polyploidy in neurons of the gastropod molluscs. II. Dynamics of DNA synthesis in the process of postnatal growth of CNS neurons in Succineid snail

A study was made of the age dynamics of polyploidization and dynamics of DNA synthesis in neuron cell nuclei during the postnatal growth of the gastropod pulmonate snail Succinea lauta. According to cytophotometrical results, the degree of polyploidization in neuron nuclei increases from young to adult individuals, varying from 2c to 16,384c. In the visceral complex, the maximum and medium ploidy values of the neuron nuclei are higher by almost 4-8 times than those in cerebral and pedal ganglia. The medium level of ploidy in adult snails increases by 5.7 times in the visceral complex of ganglia and by 4.1-4.2 times in the pedal and cerebral ganglia. According to 3H-thymidine autoradiography, DNA synthesis in neuron nuclei occurs during the whole life of the snail. In young individuals the neurons have the highest activity of DNA synthesis--the index of labeled nuclei of neurons making in total 50.2%. In older age, a steady decrease in the index of labeled nuclei is observed--in total to 35.8% and 7.0% in small and large adult snails, respectively. The state of summer hibernation completely stops DNA syntheses in neurons, but emergency from hibernation is accompanied by restoration of DNA syntheses.     

A method for investigating hepatocyte polyploidization kinetics during postnatal development in mammals.

A method for investigating weakly-proliferating cell populations of liver parenchyma on the basis of a quantitative analysis of hepatocyte polyploidization during postnatal development is described. The method uses a mathematical model which characterizes the hepatocyte polyploidization process, and incorporates data concerning the time course for relative frequencies of hepatocytes in different ploidy classes. As a result of these measurements and calculations for rat liver, transition rates of hepatocytes (the relative number of cells during a given time unit) from one ploidy class to another, and a coefficient for the reduction of hepatocyte mitotic activity with an increase in its ploidy class were obtained. Calculated curves show a good correspondence with the real process of hepatocyte frequency changes as they relate to changes in the age of the animals. To check this method, experiments investigating time changes of autoradiographic label content in the different ploidy classes of hepatocytes were carried out. By mathematically modeling the label diluting process resulting from cell proliferation and polyploidization, transition rates of hepatocytes were calculated, and they reflect values calculated from the model according to changes in occurrence frequencies.     

Analysis of the polyploidization kinetics of the parenchymal cells in the rat liver

Methodological approaches to kinetics of cell polyploidization in the rat liver parenchyma are discussed. Different ways of hepatocyte polyploidization in the course of postnatal liver growth have been assessed. The intensities of hepatocyte transitions from one ploidy class to another were determined. On the basis of literary experimental data the following is summarized: With the increase in the animal age, there is a decrease in hepatocyte transition from one ploidy class to and ther; in young animals the intensity of formation of tetraploid hepatocytes through the stage of binuclear cells (2c----2c X 2----4c) is 0.39-0.55 within two weeks, the intensity of direct transitions (2c----4c) being 0.00-0.19 within the same time. The intensity of entering to DNA synthesis is reduced with the increase in hepatocyte ploidy levels; in this case the coefficient of the reducing of mitotic activity is calculated as 0.10-0.22, and 0.01-0.05 for 4c- and 8c-hepatocytes, resp. The factors stimulating proliferation in the liver increase the intensity of the direct cell transition (2c----4c) by several times which can exceed the intensity of transition through the binuclear cell stage.     

Polyploidy: significance for cardiomyocyte function and heart aerobic capacity

Somatic polyploidy, defined as genome multiplication, was found in all differentiated mammalian tissues. The highest level of such a polyploidy was found in the myocardium. This phenomenon was shown to be associated with changes in the pattern of gene expression. Hence, polyploidization may create cells with new physiology. The effect of polyploidy on the heart function has never been studied. The aim of the present study was to investigate the effect of polyploidy on cardiomyocyte functioning and heart aerobic capacity. DNA and the total protein content, nucleolar activity reflecting the rate of rRNA synthesis and, consequently, ribosome biogenesis, were measured in ventricular myocytes isolated from the human and from 21 mammalian species by image cytometry and microscopic morphometry. The total protein content was estimated after staining slides with naphtol-yellow dye. For measurement of DNA and nucleolar area, staining with Hoechst and AgNO3 was applied. Cardiac aerobic capacity was evaluated by the heart mass to body mass ratio. A negative correlation between the heart index and the average cell ploidy was revealed (r = -0.79; P < 0.0001). The average genome number per myocyte was registered to be higher by approximately 35% in the sedentary mammals, with the heart index about 0.4% from body mass, than in the athletes with heart index about 0.6% of body mass. Polyploidization was shown to be associated with a sharp decrease in the protein/DNA ratio in cardiomyocytes. As a result, cardiomyocytes in the athletic mammals with poorly polyploid hearts have much higher protein content per genome than do cells in the sedentary species with highly polyploid hearts. Surprisingly, despite decreased protein/DNA ratio, the nucleolar area per genome significantly increased with polyploidization, indicating the imbalance between the cellular protein content and the rate of ribosome biogenesis. Such an imbalance should obviously impair cardiac function, because the additional genomes take some valuable space and biological resources from the cell, which could have been otherwise directed to the maintenance of cardiomyocyte contractile machinery. It is generally accepted that somatic polyploidy is associated with oxidative stress and energetic starvation. Thus, we suppose that additional genomes may serve for cardiomyocyte protection from oxidative damage in the hearts.     

BIN4, a novel component of the plant DNA topoisomerase VI complex, is required for endoreduplication in Arabidopsis

How plant organs grow to reach their final size is an important but largely unanswered question. Here, we describe an Arabidopsis thaliana mutant, brassinosteroid-insensitive4 (bin4), in which the growth of various organs is dramatically reduced. Small organ size in bin4 is primarily caused by reduced cell expansion associated with defects in increasing ploidy by endoreduplication. Raising nuclear DNA content in bin4 by colchicine-induced polyploidization partially rescues the cell and organ size phenotype, indicating that BIN4 is directly and specifically required for endoreduplication rather than for subsequent cell expansion. BIN4 encodes a plant-specific, DNA binding protein that acts as a component of the plant DNA topoisomerase VI complex. Loss of BIN4 triggers an ATM- and ATR-dependent DNA damage response in postmitotic cells, and this response coincides with the upregulation of the cyclin B1;1 gene in the same cell types, suggesting a functional link between DNA damage response and endocycle control.     

Somatic polyploidy promotes cell function under stress and energy depletion: evidence from tissue-specific mammal transcriptome

Polyploid cells show great among-species and among-tissues diversity and relation to developmental mode, suggesting their importance in adaptive evolution and developmental programming. At the same time, excessive polyploidization is a hallmark of functional impairment, aging, growth disorders, and numerous pathologies including cancer and cardiac diseases. To shed light on this paradox and to find out how polyploidy contributes to organ functions, we review here the ploidy-associated shifts in activity of narrowly expressed (tissue specific) genes in human and mouse heart and liver, which have the reciprocal pattern of polyploidization. For this purpose, we use the modular biology approach and genome-scale cross-species comparison. It is evident from this review that heart and liver show similar traits in response to polyploidization. In both organs, polyploidy protects vitality (mainly due to the activation of sirtuin-mediated pathways), triggers the reserve adenosine-5′-triphosphate (ATP) production, and sustains tissue-specific functions by switching them to energy saving mode. In heart, the strongest effects consisted in the concerted up-regulation of contractile proteins and substitution of energy intensive proteins with energy economic ones. As a striking example, the energy intensive alpha myosin heavy chain (providing fast contraction) decreased its expression by a factor of 10, allowing a 270-fold increase of expression of beta myosin heavy chain (providing slow contraction), which has approximately threefold lower ATP-hydrolyzing activity. The liver showed the enhancement of immunity, reactive oxygen species and xenobiotic detoxication, and numerous metabolic adaptations to long-term energy depletion. Thus, somatic polyploidy may be an ingenious evolutionary instrument for fast adaptation to stress and new environments allowing trade-offs between high functional demand, stress, and energy depletion.